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1.
根据野外露头剖面,结合区域地质资料,对塔里木盆地乌什凹陷西部的石炭系—二叠系沉积演化进行了分析。乌什凹陷西部在石炭纪夹于南天山残留海盆地和柯坪—温宿隆起之间,其地层和沉积与塔里木盆地内部有较大差异。早石炭世早期,本区为碎屑岩和碳酸盐岩混积的浅海陆棚环境,以索格当他乌断裂为界,早期的柯坪—温宿隆起控制了该时期的沉积作用。早石炭世晚期,本区首次海侵,早期的柯坪—温宿隆起部分被淹没,并伴随着强烈的构造沉降,形成半深水斜坡环境,沉积了一套以库鲁组和索格当他乌组为代表的近端—远端浊积扇的复理石沉积,并一直持续到晚石炭世早期。晚石炭世晚期,本区又一次规模较大的海侵,柯坪—温宿隆起大部分被淹没,原隆起区为开阔海台地环境,北部和西部边缘发育典型的台地边缘相生物礁,向北延伸可达乌什北的克孜布拉克地区,再向北为礁前斜坡和浅海陆棚环境,并持续到中二叠世早期。中二叠世以后,伴随周缘地区大规模的陆内火山喷发,该区发生大规模海退。晚二叠世末,随着塔里木板块与中天山地块的拼合以及海西期天山造山带的形成,南天山洋消失,结束了海相沉积,进入了陆相沉积阶段。 相似文献
2.
Felicitász Velledits 《International Journal of Earth Sciences》2006,95(3):395-412
Based on sedimentological and biostratigraphic investigations of the Middle–Late Triassic successions of the Bükk Mountains, the evolution of an upper plate margin of a rifting area was reconstructed. The Middle Anisian shallow water carbonates are succeeded by terrestrial sediments. Simultaneously with the uplift, volcanic activity starts, indicating the beginning of the rifting. The emersion was followed by rapid subsidence in the Late Anisian–Early Ladinian which corresponds to the synrift stage. Based on facies distribution of Ladinian–Carnian sediments, the half-graben structure of the basement can be outlined. Coeval existence of platforms and basins is characteristic of this period. From the end of the Fassanian, the subsidence slows down: postrift stage. At this time the thermal cooling controls the subsidence of the area. During the Late Triassic, the edges of the platforms were gradually drowned and basins conquered bigger and bigger areas. Sediments deposited on the southern shelf of the opening Vardar-Meliata branch of the Neotethys Ocean show features characteristic to the upper plate part of a rifting area, whereas sediments of the northern shelf show features characteristic to the lower plate. The opening of the Vardar-Meliata branch of the Neotethys Ocean follows the asymmetric rifting model of Wernicke (Can J Earth Sci 22:108–125, 1985) and Dixon et al. (Tectonics 8(6):1193–1216, 1989). 相似文献
3.
Martin Stefan Oczlon 《International Journal of Earth Sciences》1994,83(1):20-31
Continental margin sediments of an exotic nature, which have been thrust over the Rhenohercynian zone of Central Germany, occur mainly in olistostromes of Lower Carboniferous age. A stratigraphy compiled from the exotic rocks reflects the wide spectrum of continental shelf and adjacent basinal facies that existed at least from the Early Ordovician to the Early Carboniferous. Facies and faunal relationships are comparable with those in the Palaeozoic of the western Mediterranean region, Saxothuringia (south-east Germany) and the Barrandian area (Czech Republic), which suggests deposition at the northern margin of the Gondwana Palaeozoic supercontinent. Among the exotic rocks, a Middle Devonian to Early Carboniferous facies, referred to as Flinzkalk, contains sediments showing characteristics of contourites. They may have originated from reworked turbidites, formed under a current which flowed parallel to the North Gondwana margin, similar to the Gulf Stream flowing along eastern North America today. 相似文献
4.
H.-J. Gawlick W. Frisch A. Vecsei T. Steiger F. Böhm 《International Journal of Earth Sciences》1999,87(4):644-657
Facies analysis, fossil dating, and the study of the metamorphism in the Late Triassic to Early Cretaceous sedimentary successions in the central part of the Northern Calcareous Alps allow to reconstruct the tectonic evolution in the area between the South Penninic Ocean in the northwest and the Tethys Ocean with the Hallstatt Zone in the southeast. The Triassic as well as the Early and Middle Jurassic sediments were deposited in a rifted, transtensive continental margin setting. Around the Middle/Late Jurassic boundary two trenches in front of advancing nappes formed in sequence in the central part of the Northern Calcareous Alps. The southern trench (Late Callovian to Early Oxfordian) accumulated a thick succession of gravitatively redeposited sediments derived from the sedimentary sequences of the accreted Triassic–Liassic Hallstatt Zone deposited on the outer shelf and the margin of the Late Triassic carbonate platform. During a previous stage these sediments derived from sequences deposited on the more distal shelf (Salzberg facies zone of Hallstatt unit, Meliaticum), and in a later stage from more proximal parts (Zlambach facies zone of Hallstatt unit, Late Triassic reef belt). Low temperature–high pressure metamorphism of some Hallstatt limestones before redeposition is explained by the closure of parts of the Tethys Ocean in Middle to Late Jurassic times and associated subduction. In the northern trench (Late Oxfordian to Kimmeridgian) several hundred meters of sediment accumulated including redeposited material from a nearby topographic rise. This rise is interpreted as an advancing nappe front as a result of the subduction process. The sedimentary sealing by Tithonian sediments, documented by uniform deep-water sedimentation (Oberalm Formation), gives an upper time constraint for the tectonic events. In contrast to current models, which propose an extensional regime for the central and eastern Northern Calcareous Alps in the Late Jurassic, we propose a geodynamic model with a compressional regime related to the Kimmerian orogeny. 相似文献
5.
E. N. Gorozhanina V. M. Gorozhanin T. N. Isakova 《Stratigraphy and Geological Correlation》2018,26(2):139-156
In the conjunction zone of the East European Platform and the Uralian foredeep, involved in structures of the Southern Urals (Bashkiria), sediments deposited at the shelf zone edge in the Late Carboniferous–Early Permian crop out. The Upper Carboniferous bioherm and Lower Permian deep marine–shelf boundary limestones, composing Voskresenka Mount near Tabynsk township, were studied. Results of the complex analysis of lithofacies, paleontological, structural, and also geological and geophysical data show that the Voskresenka carbonate massif, previously attributed to a single reef structure, represents the SW-dipping tectonic horst block, composed of Upper Carboniferous shelf–bioherm limestones, which is uplifted in a near break zone. As a result of tectonic processes, the edge of the late Carboniferous carbonate platform, overlain by Asselian deep-water sediments, was exhumed. The sedimentary succession shows that the paleogeographic setting at the margin of the East European Craton changed at the Carboniferous–Permian boundary during the formation of the Ural collisional orogen. 相似文献
6.
《Sedimentary Geology》2005,173(1-4):151-185
An Early Miocene (Early Burdigalian) incised valley-fill was produced through development of an alluvial system during active extension and block rotation in the Mut Basin. Five phases of alluvial activity have been recognized and are linked to specific tectono-stratigraphic factors. The entrenchment phase (phase 1) was a response to a rapid decrease in accommodation caused by a combination of sea-level fall and accelerated tectonism that occurred around the basin during active extension. A lacustrine depositional system that pre-dated entrenchment was abruptly succeeded by an erosional fluvial system. The initial erosion, the entrenchment phase was followed by the deposition of ephemeral meandering fluvial facies and later by high sinuosity sandy meandering fluvial facies. During the aggradational phase (Phase 2), coarser-grained, lower sinuosity meandering river facies were vertically stacked in response to successive periods of fault-block rotation and basinal subsidence. The thickest stratigraphic interval was deposited during this time. Simultaneously in a basinward position, finer-grained distal facies were deposited. The succeeding backfilling phase (Phase 3) was marked by further fault-block rotation and an increase in the catchment area that resulted in higher flow regime and more sediment input. A further increase in accommodation space due to block rotation resulted in the retreat of facies belts, and the deposition of a retrogradational stacked gravelly low-sinuosity meandering facies during the early transgressive phase (Phase 4). In the downstream part of the alluvial valley, fluvio-deltaic and non-marine transitional facies were deposited and progressively retreated landwards during marine flooding. Phase 5 marks the main interval of Early Miocene marine transgression (a combination of global eustasy and regional epeiric subsidence). During this time, the facies belts within the incised valley-fill were dominated by estuarine and lagoonal facies assemblages, while the distal parts of the alluvial valley became completely flooded with marine waters. At the end of the transgressive phase, in the uppermost early Burdigalian, the estuarine and lagoonal facies migrated further inland, while shallow-marine sediments (reefal limestones) were deposited in distal parts of the now-drowned valley, blanketing the pre-existing topography. 相似文献
7.
塔里木板块内部发育了大量由早—中二叠世板内岩浆作用所形成的、以玄武岩类为主的基性岩浆岩,包括玄武岩、辉绿岩、玄武安山岩等,残余分布面积约20万km2。而二叠纪时期是塔里木板块演化过程中一个非常重要的转折时期,从早二叠世晚期开始塔里木板块结束了海相沉积,进入了陆相沉积阶段。通过对塔里木板块的岩浆作用特征和石炭纪—二叠纪沉积相的分析,笔者讨论了这一大规模的岩浆作用对板块晚石炭世—二叠纪的沉积作用所起的控制作用,提出了塔里木板块早—中二叠世巨量玄武质岩浆作用的沉积响应过程模式。 相似文献
8.
构造沉降作为盆地成因研究中的重要组成部分,对其特征进行分析有助于盆地成因的解析。本次通过对鄂尔多斯盆地内5口典型探井的多期不整合所代表的的剥蚀厚度进行恢复,结合去压实矫正模型以及平均密度、平均古水深等参数的确定,较为精确地刻画出了鄂尔多斯盆地不同构造单元自早寒武世至今的构造沉降特征,同时结合裂谷盆地瞬时拉张模型、裂后热坳陷模型以及前陆盆地挠曲模型对构造沉降曲线进行了模拟,对盆地成因进行分析。鄂尔多斯盆地中寒武世—中生代末期主要由早古生代沉降旋回、二叠—三叠纪沉降旋回与侏罗—白垩纪沉降旋回组成。其中岩石圈热冷却作用引起的沉降贯穿全地质时期。早古生代沉降旋回中,中寒武世的加速沉降主要体现在盆地南部,沉降机制为岩石圈伸展减薄,中奥陶世马家期为全盆地尺度的加速沉降,沉降机制仍为岩石圈伸展减薄。二叠—三叠纪沉降旋回中,晚二叠世—早-中三叠世为该旋回的加速沉降期,该期加速沉降具有多幕裂陷的特征。侏罗—白垩纪沉降旋回中,中侏罗世盆地南部处于缓慢沉降期,沉降机制为岩石圈热冷却作用,晚侏罗世—早白垩世,除伊盟隆起,盆地整体处于加速沉降期,沉降机制为前陆盆地引起的挠曲沉降。 相似文献
9.
The Sakoa Group is the lowermost stratigraphical succession of the Karoo Supergroup and the oldest sedimentary unit in Madagascar, spanning the Late Carboniferous through Early Permian epochs. The Sakoa Group is exposed in the southern Morondava Basin. It is predominantly a siliciclastic sequence comprising seven lithofacies associations: (1) diamictites; (2) conglomeratic sandstones; (3) sandstones; (4) interbedded thin sandstones and mudstones; (5) mudstones; (6) coals; and (7) limestones. These facies represent deposition in the early extensional stages of continental rift development. The sediments were deposited predominantly on alluvial fans, and in braided to meandering stream and overbank environments. Locally lacustrine and coal swamp environments formed in low areas of the basin floor during rift initiation. Subsidence rates remained fairly constant throughout the Early Permian and were accompanied by a gradual reduction in relief of the basin margins and an increased geomorphic maturity of the fluvial systems flowing across the basin floor. Near the end of the Early Permian the southern Morondava Basin was inundated by a marine transgression , which resulted in deposition of the Vohitolia Limestone. Subsequent tectonic uplift and erosion resulted in a regional unconformity between the Sakoa Group and the overlying Sakamena Group. 相似文献
10.
MeiMingxiang MaYongsheng DengJun GaoJinhan ChenHuijun MengQingfen LiDonghai 《中国地质大学学报(英文版)》2003,14(2):103-118
There are complex and regular changes on sedimentary facies from the Early to the Middle Triassic in the Nanpanjiang basin. After the obvious drowned event of carbonate platforms in the transitional period between Permian and Triassic, carbonate platforms have evolved into the ramp type from the rimmed-shelf type. The differentiation of sedimentary facies becomes dearer in space, which are marked by the changes from an attached platform to a turbidity basin and several isolated platforms in the basin. The striking characteristics are the development of oolitic banks on isolated platforms in Nanning and Jingxi and the reef- and bank-limestones in the margin of the attached platform in the Early Triassic. Despite the difference of the time-span and the architectnre of fades succession of third-order sedimentary sequences, the process of the third-order relative sea-level changes reflected by the sedimentary facies succession of the third-order sequences is generally synchronous. Therefore, six third-order sequences could be discerned in the strata from the Early to the Middle Triassic in the Nanpanjiang basin. Using two types of facies changing surfaces and two types of diachronisms in stratigraphic records as the key elements, the sedimentary facies architectures of the third-order sequences that represent sequence stratigraphic frameworks from the Early to the Middle Triassic in the Nanpanjiang basin could be constructed. 相似文献
11.
A. Van Heeswijck 《Australian Journal of Earth Sciences》2013,60(3):417-426
Upper Carboniferous to Lower Permian sedimentary rocks extend along the periphery of the northern Sydney Basin, a sub‐basin of the Sydney‐Gunnedah‐Bowen Basin complex. The basin contains basal basalts and volcanic sediments deposited in a nascent rift zone. This rift zone was created through crustal thinning during trench rollback on the eastern edge of the New England Orogen. Thermal subsidence created accommodation for predominantly marine Dalwood Group sediments. Clastic sedimentation then occurred in the Maitland‐Cessnock‐Greta Coalfield and Cranky Corner Basin during the Early Permian. This occurred on a broad shelf undergoing renewed thermal subsidence on the margin of a rift flank of the Tamworth Belt of the southern New England Orogen. Braidplain fans prograded or aggraded in two depositional sequences. The first sequence commences near the top of the Farley Formation and includes part of the Greta Coal Measures, while the second sequence includes the majority of the Greta Coal Measures and basal Branxton Formation. Thin, areally restricted mires formed during interludes in a high sedimentation regime in the lowstand systems tracts. As base‐level rose, areally extensive mires developed on the transgressive surface of both sequences. A paludal to estuarine facies changed to a shallow‐marine facies as the braidplain was transgressed. The transgressive systems tracts continued to develop with rising relative sea‐level. Renewed uplift in the hinterland resulted in the erosion of part of the transgressive systems tract and all of the highstand systems tract of the lower sequence. In the upper sequence a reduction in relative sea‐level rise saw the development of a deltaic to nearshore shelf highstand systems tract. Extensional dynamics caused a fall in relative base‐level and the development of a sequence boundary in the Branxton Formation. Finally, renewed thermal subsidence created accommodation for the overlying, predominantly marine Maitland Group. 相似文献
12.
《International Geology Review》2012,54(5):469-477
The Late Precambrian through Silurian tectonic evolution of east-central South China is modeled in terms of a history of rift, drift, and collision during Late Proterozoic, Sinian, and Late Ordovician-Early Silurian times, respectively. We review the regional stratigraphie development of this area, focusing particularly on north-central Hunan province, and argue from our observations and those of others that the Jiangnan, Xuefeng, and Jiuling ranges of the Nanling realm approximately demarcate the paleogeographic transition in Sinian to Ordovician times of shelf to off-shelf environments developed along a passive-type continental margin that started rifting in the pre-Sinian Late Proterozoic. The rift sequence is recorded by the Penhsi (= Banxi) Group, which rests unconformably above an older-presumed Middle to early Late Proterozoic-low-grade metamorphic basement. The Penhsi varies markedly in thickness but is everywhere characterized by nonmarine to paralic clastic facies. The Penhsi conformably to disconformably underlies the Sinian through Lower Paleozoic sequence throughout central South China, which developed along an E-facing, passive-type continental margin. This passive-type margin was destroyed by the Guangxian Orogeny. The Guangxian Orogeny was marked initially by the northwestward progradation of deep-marine turbidites of Late Ordovician age in the most off-shelf regions, progressing to earliest Silurian age on the shelf to the northwest. Folding and concomitant thrusting in the off-shelf regions, and subsequent erosion beneath the unconformably overlying nonmarine Middle Devonian strata, truncate the stratigraphie record of the orogen within the Early Silurian. Farther northwest, in regions undisturbed by the Guangxian Orogeny, Silurian foreland-basin sedimentation included the entire Lower Silurian succession, which grades rapidly upward from basinal to inter-tonguing marine and nonmarine elastics. This reflects a change from flexurally induced subsidence first outpacing local sedimentation, followed by sedimentation outstripping and then keeping pace with subsidence. 相似文献
13.
John R. Graham 《Sedimentary Geology》1975,13(4):267-290
The rocks described belong to the predominantly siliceous Cork Beds of Late Devonian and Early Carboniferous age. The basal unit of the Cork Beds shows a generally coarsening upwards sequence reflecting the gradual migration of barrier beach over tidal flat environments. After a minor non-depositional phase, this is succeeded by a sequence of offshore subtidal sediments which gradually fine upwards. In the higher parts of the succession subsidence exceeded sedimentation to give deeper water conditions in Visean times. In the area described the Cork Beds successions are much thinner than in areas to the east and northwest. No marked diachroneity is present and thus the existence of a relatively positive area is indicated. 相似文献
14.
DARIUSZ KRZYSZKOWSKI 《Sedimentology》1993,40(4):623-644
The Kleszczów Graben in central Poland was formed by late Oligocene to Middle Pleistocene extensional tectonics. During the Pleistocene it was infilled with a 200 m thick sequence of predominantly glacial sediments. Four distinct formations of Elsterian and Saalian age are identified, each containing 15–40 m of glaciolacustrine strata. The boundaries between formations are marked by erosional surfaces and, in part, by angular discordances caused by tectonism. Glaciolacustrine sedimentation was tectonically controlled: the thickness of the sequences in the graben are three to five times greater than outside the area of fault-controlled subsidence. Deposition in the proglacial lakes was controlled by differential subsidence rates within the basin: deep-lake facies (varved clays) were deposited in sub-basins with high subsidence rates and deltaic to shallow-water facies accumulated in areas of moderate subsidence or occasional uplift. These variations led to the development of a very complex, ‘mosaic’ of lateral facies relationships, suggesting that several sub-basins with differing subsidence rates were present. The Vertical successions show proximal-distal sequences typical of glacier-fed lakes that have limited contact with the ice sheet. However, gravity flow facies are very common, and occur both in the shallow- and deep-water deposits. These deposits are interpreted to have been formed adjacent to active fault scarps which bordered the lake basin. Although several distinct phases of glaciolacustrine sedimentation occurred during the history of trough infilling, the location of the areas of high subsidence varied through time. 相似文献
15.
Cephalopod limestone deposition on a shallow pelagic ridge: the Tafilalt Platform (upper Devonian, eastern Anti-Atlas, Morocco) 总被引:1,自引:0,他引:1
As a result of early Variscan tectonic movements and of differential subsidence, a platform and basin topography was created along the northern margin of the Sahara Craton during the late Devonian. In the Moroccan Anti-Atlas Mountains, the Tafilalt Platform is an approximately N-S running ridge which developed since the late Middle Devonian. It separated a slowly subsiding shallow basin in the east (Tafilalt Basin) from a rapidly subsiding furrow in the west (Mader Basin). Platform deposits are characterized by highly reduced thicknesses, shallow subtidal to supratidal deposits in the late Frasnian and by unconformities at the Lower/Upper Frasnian and the Frasnian/Famennian boundaries. After a local transgression over emergent areas in the north, water depth probably never reached more than several tens to about 100 m in the lower Famennian. Cephalopod limestones of this age, deposited on the platform, represent a very diverse facies pattern comprising quartz-rich brachiopod coquinas, crinoidal limestones, thick-bedded cephalopod limestones and nodular limestones. Sedimentation rates ranged from 1 to 5 mm/ 1000 yr. In the late Famennian more uniform marl and nodular limestone facies suggest slightly deeper environments. Platform margins are characterized by higher rates of subsidence, debris flow deposits and slump structures. In the relatively shallow Tafilalt Basin, marls with intercalated nodular limestones were deposited. In the Mader Basin, sandy and calcareous turbidites suggest deeper water conditions in the late Devonian. During the Strunian/Tournaisian the whole area was overwhelmed by a thick deltaic sequence. The general facies distribution is in agreement with depositional models of other Upper Devonian and Lower Carboniferous cephalopod limestones in the European Variscan orogenic belts. In all these cases, condensed cephalopod limestones occupy a distinct palaeogeographic position in predictable facies sequences that reflect pre-orogenic phases in the Variscan geodynamic cycle. Moreover, close parallels exist with condensed sequences in the Triassic and Jurassic that occur in a very similar position within the Alpine orogenic cycle. 相似文献
16.
Andrzej Pszczółkowski Ryszard Myczyński 《Journal of South American Earth Sciences》2010,29(2):225-253
In the Guaniguanico Mountains of western Cuba, the Late Jurassic–Early Cretaceous limestones occur in three stratigraphic successions, which have accumulated along the proto-Caribbean margin of North America. The Late Jurassic subsidence and shallow-water carbonate deposition of the Guaniguanico successions have no counterpart on the northeastern Maya block, but some distant similarities with the southeastern Gulf of Mexico may exist. Four facies types have been distinguished in the Tithonian–Lower Valanginian deposits of the Guaniguanico tectonic units. Drowning of the Late Jurassic carbonate bank of the Sierra de los Organos occurred at the Kimmeridgian/Tithonian boundary. During this boundary interval, sedimentation in the west Cuban area and southwestern margin of the Maya block (Mexico) has evolved in a similar way in response to a major second-order transgression.The Lower Tithonian ammonite assemblages of the Guaniguanico successions indicate, in general, the neritic zone. Presence of juvenile gastropods and lack of adult specimens suggest unfavorable environment for these molluscs, probably related to low oxygenation levels. The Early Tithonian transgressive phase terminated about the lower boundary of the Chitinoidella Zone. The Late Tithonian “regressive” phase is weakly marked, whereas the latest Tithonian–earliest Berriasian strata were deposited during a deepening phase. The latter transgressive phase has ended in the Late Berriasian Oblonga Subzone. We correlate the bioturbated pelagic biomicrites of the Tumbitas Member of the Guasasa Formation with a significant fall of the sea level during the latest Berriasian–Early Valanginian. The average sedimentation rate for the Tumbitas Member biomicrites was about three times faster than for the Berriasian Tumbadero Member limestones. Sedimentation rates for the Tumbitas Member and the Valanginian limestones at the DSDP Site 535 in the southeastern Gulf of Mexico were similar. In the Los Organos succession, the Late Valanginian transgressive interval is associated with radiolarian limestones and black chert interbeds in the lower part of the Pons Formation. In the Southern Rosario succession, the pelagic limestones pass into the radiolarian cherts of the Santa Teresa Formation indicating a proximity of CCD during Late Valanginian–Hauterivian times. 相似文献
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Dr. Heinrich Bahlburg Dr. Christoph Breitkreuz Prof. Dr. Werner Zeil 《International Journal of Earth Sciences》1987,76(2):633-646
The oldest non-metamorphic sediments of northern Chile (21?–27?S) are of Early Ordovician age. The partly strong volcanic influence in the clastic series of the Pre-Cordillera and the Puna might be connected with the extensive Ordovician magmatism on the eastern side of the Argentinian Puna. The geochemical character of the tholeiitic intercalations in the pelites and turbidites of the »Complejo Igneo-Sedimentario del Cordon de Lila« (C.I.S.L.) in the Pre-Andean Depression indicates a ?Lower Ordovician extensional regime in this area. A positive area (»Arco Puneño«) encompassing the whole width of the present-day western Central Andes developed during the subsequent orogenic phase (»Fase Oclóyica«), resulting in the absence of Silurian strata in Northern Chile. During the Devonian/Carboniferous, two areas of marine facies can be distinguished. In the Coastal Cordillera thick flysch sediments were deposited longitudinally in a N-S striking trough. In the east, in what is now the Pre-Andean Depression and High Cordillera, thick sandstone series accumulated on the western shelf of the Arco Puneno. Carboniferous tectonic movements led to the formation of a shallow marine platform in the west on which clastic sediments, limestones and volcanics were deposited during the Upper Carboniferous-Permian. Simultaneously, extensive volcanism developed in the Pre- and High Cordillera accompanied by predominantly terrestrial sedimentation. A general westward migration of the orogenic zones took place along with repeated phases of rifting and accretion in the Central Andes during the Paleozoic. Eastward directed erosive subduction prevailed since the breakup of Pangea. 相似文献
20.
台盆相间是桂东北泥盆纪和石炭纪沉积的重要特色,而D/C界线又是台盆相间沉积最突出的一个时段之一。文章回顾并评述了桂东北D/C界线的研究历程、相序划分、主要代表剖面,认为桂东北D/C界线可划分为碎屑岩相序和碳酸盐岩相序以及它们的过渡类型。通过对20条典型剖面的岩性组合特征对比,恢复了桂东北D/C界线海平面相对下降期的岩相古地理,结果显示桂东北在该时期主要存在柳州、桂林两大台地以及多个小型台地,台地间普遍发育快速相变的台沟、盆地沉积,石炭纪初期海水变浅,台地分布范围显著扩大,江南古陆供给增强,台盆相间格局迅速发展。为了进一步探讨桂东北D/C界线的演化过程和背后的控制因素,文章分析了广西整体的台盆相间演化的阶段性、同沉积构造作用以及海平面变化的影响,梳理了台盆相间演化过程中沉积环境分异与构造运动- 海平面的关系,认为在滇黔桂裂谷盆地在持续断陷发展的前提下,桂东北D/C界线沉积分异的主要原因可能是受冈瓦纳大陆冰川形成与消融导致的海平面异常波动,以及柳江运动引发的局部同沉积断陷强度差异变动影响,且构造和沉积要素在D/C界线的耦合作用达到最强,最终促进桂东北台盆相间格局在D/C界线达到鼎盛。在此模式下,可以将台盆相间的演化划分为4个阶段,早泥盆世中期—晚期为台盆相间格局的孕育期,早泥盆世晚期—中泥盆世晚期沉积开始分异,为台盆相间格局的发展期,晩泥盆世—早石炭世台- 盆出现强烈分割,海平面异常下降和柳江运动同时作用于沉积,为台盆相间格局的鼎盛期,早石炭世之后,台盆相间沉积维持了一定时期的强度,晚石炭世开始海水逐步恢复正常后台盆相间逐渐减弱,为台盆相间格局的衰退期。 相似文献